A 117-kb microdeletion removing HOXD9-HOXD13 and EVX2 causes synpolydactyly.
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Studies in mouse and chick have shown that the 5' HoxD genes play major roles in the development of the limbs and genitalia. In humans, mutations in HOXD13 cause the dominantly inherited limb malformation synpolydactyly (SPD). Haploinsufficiency for the 5' HOXD genes has recently been proposed to underlie the monodactyly and penoscrotal hypoplasia in two children with chromosomal deletions encompassing the entire HOXD cluster. Similar deletions, however, have previously been associated with split-hand/foot malformation (SHFM), including monodactyly. Here we report a father and daughter with SPD who carry a 117-kb microdeletion at the 5' end of the HOXD cluster. By sequencing directly across the deletion breakpoint, we show that this microdeletion removes only HOXD9-HOXD13 and EVX2. We also report a girl with bilateral split foot and a chromosomal deletion that includes the entire HOXD cluster and extends approximately 5 Mb centromeric to it. Our findings indicate that haploinsufficiency for the 5' HOXD genes causes not SHFM but SPD and point to the presence of a novel locus for SHFM in the interval between EVX2 and D2S294. They also suggest that there is a regulatory region, upstream of the HOXD cluster, that is responsible for activating the cluster as a whole. (+info)
Outcome of fetal talipes following in utero sonographic diagnosis.
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OBJECTIVES: To examine the association between fetal talipes and other defects, and outcome in relation to postnatal surgery. METHODS: All cases of talipes presenting to the fetal medicine unit between 1993 and 1998 and cases of isolated talipes presenting to the ultrasound department between 1991 and 1998 were examined. The infants were followed-up to determine the number of cases that had structural or positional talipes and the number of cases requiring surgery. RESULTS: There were 76 cases, 59 of which attended the fetal medicine unit and 17 the ultrasound department. Postnatal follow-up details were available in 31 of the 40 live births. There were three neonates with unilateral talipes at birth who were thought to have bilateral talipes on prenatal ultrasound and one neonate had bilateral talipes at birth who had been thought to have unilateral talipes prenatally. In two (6.4%) neonates in whom talipes was not confirmed at birth the abnormality was diagnosed prenatally. Of the 29 neonates with confirmed talipes at birth, the defect was structural in 26 (90%) cases and positional in three. Surgery was necessary in 21 (72%) of the 29 cases and 18 (86%) of those undergoing surgery required only one operation. When live births with associated anomalies were excluded, there were 24 cases with confirmed isolated talipes and 18 (75%) required surgery. CONCLUSIONS: This study provides long-term outcome data which can be used to complement current prenatal counseling and shows that in cases of fetal talipes diagnosed prenatally, 90% have a structural rather than a positional deformity. For isolated talipes three quarters of children will require surgery and in the majority of cases only one operation on the foot is necessary. Parents should be made aware of the small possibility of a false-positive diagnosis and discrepancy between the ultrasound and postnatal diagnoses of laterality. (+info)
The Dlx5 and Dlx6 homeobox genes are essential for craniofacial, axial, and appendicular skeletal development.
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Dlx homeobox genes are mammalian homologs of the Drosophila Distal-less (Dll) gene. The Dlx/Dll gene family is of ancient origin and appears to play a role in appendage development in essentially all species in which it has been identified. In Drosophila, Dll is expressed in the distal portion of the developing appendages and is critical for the development of distal structures. In addition, human Dlx5 and Dlx6 homeobox genes have been identified as possible candidate genes for the autosomal dominant form of the split-hand/split-foot malformation (SHFM), a heterogeneous limb disorder characterized by missing central digits and claw-like distal extremities. Targeted inactivation of Dlx5 and Dlx6 genes in mice results in severe craniofacial, axial, and appendicular skeletal abnormalities, leading to perinatal lethality. For the first time, Dlx/Dll gene products are shown to be critical regulators of mammalian limb development, as combined loss-of-function mutations phenocopy SHFM. Furthermore, spatiotemporal-specific transgenic overexpression of Dlx5, in the apical ectodermal ridge of Dlx5/6 null mice can fully rescue Dlx/Dll function in limb outgrowth. (+info)
The p63 gene in EEC and other syndromes.
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Several autosomal dominantly inherited human syndromes have recently been shown to result from mutations in the p63 gene. These syndromes have various combinations of limb malformations fitting the split hand-split foot spectrum, orofacial clefting, and ectodermal dysplasia. The p63 syndrome family includes the EEC syndrome, AEC syndrome, ADULT syndrome, limb-mammary syndrome, and non-syndromic split hand/foot malformation. The pattern of heterozygous mutations is distinct for each of these syndromes. The functional effects on the p63 proteins also vary between syndromes. In all of these syndromes, the mutation appears to have both dominant negative and gain of function effects rather than causing a simple loss of function. (+info)
Split hand and foot malformation: ultrasound detection in the first trimester.
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The split hand split foot malformation is a rare disorder inherited in an autosomal dominant pattern with variable expression. In our case it was detected early by ultrasound in the twelfth week of gestation. To our knowledge, this is the earliest finding by ultrasound of this malformation. The sonographic findings were bilateral split hands and split foot. No other associated malformation was observed. The pathological findings were consistent with the diagnosis of split hand split foot malformation. Prenatal diagnosis, the genetic background, and the differential diagnosis are discussed. (+info)
Sorting nexin 3 (SNX3) is disrupted in a patient with a translocation t(6;13)(q21;q12) and microcephaly, microphthalmia, ectrodactyly, prognathism (MMEP) phenotype.
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A patient with microcephaly, microphthalmia, ectrodactyly, and prognathism (MMEP) and mental retardation was previously reported to carry a de novo reciprocal t(6;13)(q21;q12) translocation. In an attempt to identify the presumed causative gene, we mapped the translocation breakpoints using fluorescence in situ hybridisation (FISH). Two overlapping genomic clones crossed the breakpoint on the der(6) chromosome, locating the breakpoint region between D6S1594 and D6S1250. Southern blot analysis allowed us to determine that the sorting nexin 3 gene (SNX3) was disrupted. Using Inverse PCR, we were able to amplify and sequence the der(6) breakpoint region, which exhibited homology to a BAC clone that contained marker D13S250. This clone allowed us to amplify and sequence the der(13) breakpoint region and to determine that no additional rearrangement was present at either breakpoint, nor was another gene disrupted on chromosome 13. Therefore, the translocation was balanced and SNX3 is probably the candidate gene for MMEP in the patient. However, mutation screening by dHPLC and Southern blot analysis of another sporadic case with MMEP failed to detect any point mutations or deletions in the SNX3 coding sequence. Considering the possibility of positional effect, another candidate gene in the vicinity of the der(6) chromosome breakpoint may be responsible for MMEP in the original patient or, just as likely, the MMEP phenotype in the two patients results from genetic heterogeneity. (+info)
Pathogenesis of split-hand/split-foot malformation.
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Split-hand/split-foot malformation (SHFM), also known as ectrodactyly, is a congenital limb malformation, characterized by a deep median cleft of the hand and/or foot due to the absence of the central rays. SHFM may occur as an isolated entity or as part of a syndrome. Both forms are frequently found in association with chromosomal rearrangements such as deletions or translocations. Detailed studies of a number of mouse models for ectrodactyly have revealed that a failure to maintain median apical ectodermal ridge (AER) signalling is the main pathogenic mechanism. A number of factors complicate the identification of the genetic defects underlying human ectrodactyly: the limited number of families linked to each SHFM locus, the large number of morphogens involved in limb development, the complex interactions between these morphogens, the involvement of modifier genes, and the presumed involvement of multiple genes or long-range regulatory elements in some cases of ectrodactyly. So far, the only mutations known to underlie SHFM in humans have been found in the TP63 gene. The identification of novel human and mouse mutations for ectrodactyly will enhance our understanding of AER functions and the pathogenesis of ectrodactyly. (+info)
Preferential paternal origin of microdeletions caused by prezygotic chromosome or chromatid rearrangements in Sotos syndrome.
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Sotos syndrome (SoS) is characterized by pre- and postnatal overgrowth with advanced bone age; a dysmorphic face with macrocephaly and pointed chin; large hands and feet; mental retardation; and possible susceptibility to tumors. It has been shown that the major cause of SoS is haploinsufficiency of the NSD1 gene at 5q35, because the majority of patients had either a common microdeletion including NSD1 or a truncated type of point mutation in NSD1. In the present study, we traced the parental origin of the microdeletions in 26 patients with SoS by the use of 16 microsatellite markers at or flanking the commonly deleted region. Deletions in 18 of the 20 informative cases occurred in the paternally derived chromosome 5, whereas those in the maternally derived chromosome were found in only two cases. Haplotyping analysis of the marker loci revealed that the paternal deletion in five of seven informative cases and the maternal deletion in one case arose through an intrachromosomal rearrangement, and two other cases of the paternal deletion involved an interchromosomal event, suggesting that the common microdeletion observed in SoS did not occur through a uniform mechanism but preferentially arose prezygotically. (+info)